Presentation is loading. Please wait.

Presentation is loading. Please wait.

Feedback: Part C – Oscillators Slides taken from:

Similar presentations


Presentation on theme: "Feedback: Part C – Oscillators Slides taken from:"— Presentation transcript:

1 Feedback: Part C – Oscillators Slides taken from:
A.R. Hambley, Electronics, © Prentice Hall, 2/e, 2000

2 Figure 9.67 Repetitive ramp waveform.
Oscillators Oscillators are circuits that generate periodic signals An oscillator converts DC power from the power supply into AC signal power spontaneously - without the need for an AC input source Figure Repetitive ramp waveform.

3 a feedback network in a loop.
Linear Oscillators Figure A linear oscillator is formed by connecting an amplifier and a feedback network in a loop.

4 Figure 9.69 Linear oscillator with external signal Xin injected.
Barkhausen Criterion Figure Linear oscillator with external signal Xin injected.

5 Barkhausen Criterion

6 How does the oscillation get started?
Noise signals and the transients associated with the circuit turning on provide the initial source signal that initiate the oscillation

7 Practical Design Considerations
Usually, oscillators are designed so that the loop gain magnitude is slightly higher than unity at the desired frequency of oscillation This is done because if we designed for unity loop gain magnitude a slight reduction in gain would result in oscillations that die to zero The drawback is that the oscillation will be will be slightly distorted (the higher gain results in oscillation that grows up to the point that will be clipped)

8 Figure 9.70 Typical linear oscillator.
Example of Oscillator circuit (1) Figure Typical linear oscillator.

9 Example of Oscillator circuit (2)
Figure Feedback network. Note that the input to the network is on the right-hand side and the response is on the left-hand side.

10 Figure 9.73 Wien-bridge oscillator.

11 Figure 9.75 Example of output voltage of the oscillator.
Wien-Bridge oscillator output Figure Example of output voltage of the oscillator.

12 Methods for Amplitude Stabilization
In a linear oscillator, amplitude stabilization below the amplifier clipping level is needed to reduce distortion We can reduce the amount of distortion by reducing the amplifier gain However, if the gain becomes too small the oscillations die out Several approaches can be used to resolve the conflict The easiest approach is to make the gain adjustable by using a potentiometer in place of the resistors that determine the gain

13 HP way to Amplitude Stabilization
Figure Oscillation amplitude can be stabilized within the linear range of the op amp by substituting a low-power lamp for R1.

14 Figure 9.77 Amplitude stabilized Wien-bridge oscillator.
Amplitude Stabilization with diodes Figure Amplitude stabilized Wien-bridge oscillator.

15 Figure 9.78 Output voltage of the oscillator of Figure 9.77.
Amplitude Stabilization with diodes Figure Output voltage of the oscillator of Figure 9.77.


Download ppt "Feedback: Part C – Oscillators Slides taken from:"

Similar presentations


Ads by Google